Environmental seal maximizing sensor space beneath a button positioned in trim

ABSTRACT

An environmental seal is formed around a square sensor disposed beneath a circular button cap within a button assembly. The button assembly includes shelf portions each extending separately into the interior of the assembly from a sidewall of the assembly. Portions of the sidewall are exposed between the shelf portions large enough to permit the four corners of the square sensor to contact the sidewall. The button cap is set above the sensor, resting upon the shelf portions. A first sealant bonds the top faces of the shelf portions to the bottom of the button cap. A second sealant bonds the edges of the sidewall to the corners of the sensor. The second sealant interfaces with the first sealant to form a complete environmental seal.

TECHNICAL FIELD

This disclosure generally relates to an environmental seal for a buttonassembly containing a sensor.

BACKGROUND

Portable electronic devices are becoming increasingly popular. Examplesof such devices include cell phones and tablet computers. These devicesmay be subjected to a number of different environments as the usertransports them from place to place, increasing exposure to dust, lint,moisture and other foreign matter that can enter apertures of a devicehousing and interfere with device operation. Accordingly, many portableelectronic devices are manufactured with a number of environmental sealswhich prevent or impede the ingress of foreign matter.

In order to add additional buttons, sensors, or other components to anelectronic device, additional environmental seals may be used. However,portable electronic devices are also generally small in size, so thespace for both components and seals is limited.

Accordingly, there may be a present need for an environmental seal thateffectively prevents ingress of foreign matter while maximizingavailable space within a sealed interior volume of a portable electronicdevice.

SUMMARY

This application discloses techniques for forming an environmental sealaround a sensor disposed beneath a button cap. In certain embodiments,the sensor may be a fingerprint sensor which can receive informationwith respect to fingerprint images, and which can be incorporated intodevices using fingerprint recognition. For example, the fingerprintsensor can be disposed beneath a control button or display element forfingerprint recognition and authentication while the device is beingoperated by a user.

Embodiments described herein may relate to or take the form of a sealedvolume with a first and second shelf portion extending separately intothe interior of the volume from a sidewall of the volume so as to exposeat least a first portion of sidewall between the first and second shelfportions. In addition, a first adhesive of one type can be applied to atop face of the first shelf portion, and a second adhesive of the sametype can be applied to a top face of the second shelf portion. A cap canbe positioned to extend across the interior volume to adhere to both thefirst adhesive and the second adhesive. A third adhesive of a secondtype can be applied to adhere the edge of the cap to the at least afirst portion of exposed interior sidewall.

In further embodiments, the first adhesive type may be a heat activatedfilm, and the second adhesive type may be a liquid adhesive.

In further embodiments, the two adhesive types may be cured in the sameprocess, or in alternate embodiments, the adhesives may be cured indifferent processes.

Other embodiments described herein may relate to or take the form of abutton assembly with a first and a second shelf portion that may extendseparately into the interior of the assembly from a sidewall of theassembly so as to expose at least a first portion of sidewall betweenthe first and second shelf portions. A cap may be positioned to extendacross the assembly to rest on top of both the first and second shelfportions. A sensor may be positioned below the cap such that at least afirst portion of the sensor extends to meet the at least a first portionof sidewall, and at least a second portion of the sensor extends towardthe edges of the first and second shelf portions. Below the sensor, aswitch portion may be positioned.

In further embodiments, the button assembly may be circular and thesensor may be square. In some cases, a square sensor may have eachcorner meet a portion of the sidewall of the circular assembly.

Other embodiments described herein may relate to or take the form of amethod of sealing a volume. An assembly may be selected to have aninterior volume including at least a first and second shelf portionextending separately into the interior of the volume from a sidewall ofthe volume so as to expose at least a first portion of sidewall betweenthe first and second shelf portions. A first adhesive of a firstadhesive type may be applied to a top face of the first shelf portion,and a second adhesive of the first adhesive type may be applied to a topface of the second shelf portion. A cap may be positioned to extend toadhere to both the first adhesive and the second adhesive. Finally, athird adhesive of a second adhesive type may be applied to adhere thecap to the at least a first portion of exposed interior sidewall.

In further embodiments, the selected assembly may be cylindrical orcircular.

In further embodiments, the first adhesive type may be a heat activatedfilm and the second adhesive type may be a liquid adhesive. These twoadhesive types may be cured in the same process or in differentprocesses. In some embodiments, the second adhesive may be jet injected.

Other embodiments described herein may relate to or take the form of amethod of sealing a volume. An assembly maybe be selected to have aninterior volume including at least a first and second shelf portionextending separately into the interior of the volume from a sidewall ofthe volume so as to expose at least a first portion of sidewall betweenthe first and second shelf portions. A cap may be positioned to extendto rest over top portions of the first and second shelf portion. Atemporary adhesive dam may be applied below the cap such that the cap israised slightly above the first and second shelf portion. An adhesivemay be injected to adhere the cap to the first portion of the sidewallin an amount sufficient to also adhere the top portions of the first andsecond shelf portions to the cap. The adhesive may be cured and thetemporary adhesive dam may be removed.

In further embodiments, the adhesive type may be a heat activated filmor a liquid adhesive.

In further embodiments, the assembly may be cylindrical and thetemporary adhesive dam may be a sticker.

BRIEF DESCRIPTION OF THE DRAWINGS

Reference will now be made to representative embodiments illustrated inthe accompanying figures. It should be understood that the followingdescriptions are not intended to limit the embodiments to one preferredembodiment. To the contrary, it is intended to cover alternatives,modifications, and equivalents as may be included within the spirit andscope of the described embodiments as defined by the appended claims.

FIG. 1 is an isometric view of an example embodiment of a portableelectronic device.

FIG. 2 is an enlarged detail top view of a button of the portableelectronic device of FIG. 1.

FIG. 3 is a top plan view of a portion of button assembly for receivingan environmental seal.

FIG. 4A is an isometric side view of an exploded button assembly showinga button cap and a first portion of the environmental seal of FIG. 3.

FIG. 4B is an isometric side view of the button assembly of FIG. 4A.

FIG. 5 is a fragmentary view of a schematic cross section of thelaminated layers of a button and sensor assembly taken along line 5-5 ofFIG. 3

FIG. 6 is a fragmentary view of a schematic cross section of thelaminated layers of a button and sensor assembly taken along line 6-6 ofFIG. 3

FIG. 7 is a top plan view of the button assembly of FIG. 4A showing aboth a first portion and a second portion of an environmental seal.

FIG. 8 is a flowchart illustrating an exemplary process of providing atwo-part environmental seal.

FIG. 9 is a flowchart illustrating another exemplary process ofproviding an environmental seal.

DETAILED DESCRIPTION

Various embodiments of an environmental seal that effectively preventsingress of foreign matter while maximizing available space within asealed interior volume of a component assembly for use within a portableelectronic device are discussed herein. In certain embodiments, aninterior volume of a component assembly may house at least a button anda sensor. A button cap may provide an engagement surface for a user tointeract with the button, thereby providing an input to the electronicdevice. In certain embodiments, the button may also provide a tactilefeedback effect from pushing or releasing the button. The button cap mayextend from the interior volume, through an aperture, to the exteriorsurface of the component assembly. In certain designs, the sensor may bepositioned directly below the button cap, but above the button itself.

In certain embodiments, the sensor may be a fingerprint sensor such thatuser authentication can be performed while the device is being operatedby a user. The fingerprint sensor may utilize a grid of capacitiveelements for capturing the fingerprint image or, in alternateembodiments, an optical sensor or other suitable fingerprint imagingtechnology. A control circuit can also be provided, for example, abutton or switch element responsive to touch or pressure. In somedesigns, the fingerprint sensor can be utilized in combination with abutton or display element formed with an anisotropic dielectric materialsuch as sapphire.

In certain designs, the fingerprint sensor exhibits capacitive couplingwith the ridges and valleys of the user's finger, such as at theepidermis of the user's finger, with the effect that the fingerprintsensor receives two-dimensional fingerprint image information, fromwhich the electronic device can determine whether the fingerprint is theuser's fingerprint or some other person's fingerprint. The fingerprintrecognition sensor circuit might also or instead exhibit capacitivecoupling with another portion of the user's finger, such as a subdermallayer thereof, or with another feature of the user's finger.

One may appreciate that foreign matter above, proximate, or below thesensor may interfere with capacitive coupling between the sensor and theridges and valleys of the user's finger, which in turn may cause the twodimensional fingerprint information read by the sensor to be inaccurate,which in turn may cause the electronic device to incorrectly reject auser's fingerprint, or in other cases, incorrectly authenticate someother person's fingerprint as the user. In such a case, the interiorvolume of the component assembly may be sealed with an environmentalseal to prevent ingress of foreign matter that may interfere withoperation of both the button and the sensor.

In certain embodiments, the environmental seal may be disposed along theedges of the button cap, bonding it with the internal sidewalls of anaperture within the component assembly. In certain other embodiments,the environmental seal may be disposed upon a shelf within the aperturesupporting the button cap along its perimeter. In further embodiments,the environmental seal may be disposed proximate edges of the sensoritself such that the sensor is bonded with at least a portion of theinternal sidewalls of the aperture within the component assembly. Incertain designs in which the sensor takes a rectangular shape, theenvironmental seal may be disposed along the four corners of the sensor.

In some embodiments the button cap and sensor may be of differentshapes. For example the button cap may be circular and the sensor may besquare. In further embodiments, a sensor of large area may provideadequately detailed information. In such an embodiment, the maximum areaa square sensor may occupy below a circular button cap is equal to thearea of the circle's inscribed square. In these embodiments, thecomponent assembly may include only a partial perimeter shelf within theaperture such that gaps in the shelf permit the corners of the squaresensor to fully extend to the edges of the button cap. In such anembodiment, an environmental seal may be composed of multiple portions.For instance, first portion of an environmental seal may be disposedalong the partial perimeter, and a second portion of an environmentalseal may be disposed along the edges of the button cap not supported bythe partial perimeter. The first and second portions may collaborate toform a unitary environmental seal around the entire perimeter of thebutton cap.

In some embodiments, individual portions of a multi-portionenvironmental seal may be fabricated from separate materials. Forexample, a first portion of an environmental seal may comprise a heatactivated film and a second portion may comprise a liquid adhesive. Inother embodiments, individual portions may be fabricated from the samematerial.

In certain embodiments, individual portions of a multi-portionenvironmental seal may be disposed in separate processes. For example,one portion may be disposed in a first manufacturing process, and asecond portion may be disposed during a subsequent manufacturingprocess. In certain embodiments, although multiple portions may bedisposed at different times, they may be cured simultaneously bysubjecting the entire uncured multi-portion environmental seal toappropriate curing conditions (e.g., heat or ultraviolet light).However, in certain embodiments, portions of an environmental seal maybe cured at different times.

FIG. 1 is a front isometric view of an exemplary portable electronicdevice 100, incorporating an environmental seal (not shown). Theelectronic device 100 may include a button cap 110 which provides anengagement surface for a user to interact with an associated button (notshown).

FIG. 2 is an enlarged detail view of a circular button cap 110 of theportable electronic device 100 shown and partially described inreference to FIG. 1. Also shown is square sensor 300, illustrated belowbutton cap 110. As shown, square sensor 300 occupies the maximum areapossible while remaining bounded by the circumference of the circularbutton cap 110. In other words, the square sensor 300 is an inscribedsquare within circular button cap 110. In some embodiments, circularbutton cap 110 may be translucent, selectively translucent, orsemi-translucent in order for sensor 300 to properly function. Sensor110 may be an accelerometer, gyroscope, inertial measurement unit,global positioning sensor, proximity sensor, imaging sensor or any othersensor suitable for inclusion within electronic device 100. In certainembodiments, square sensor 300 may be a fingerprint imaging sensor.

The fingerprint imaging sensor 300 may also include an integratedcircuit with one or more capacitive plates arranged in a two dimensionalarray. Each such capacitive plate may be disposed for collecting atleast some fingerprint image information in response to the capacitivecoupling with the ridges and valleys of the user's finger at one or morepixels in an array. This has the effect that, while each capacitiveplate collects one or more pixels of fingerprint image information in anarray, the set of those capacitive plates collectively receives a twodimensional array of fingerprint image information. For example, a twodimensional array of fingerprint image information can be used todetermine substantial features of the user's fingerprint, which can beused to enroll the user's fingerprint in a database for later use, tocompare at a later time against enrolled fingerprint image informationto authenticate the user's fingerprint, and possibly to reject anotherperson's fingerprint as not matching any enrolled user's fingerprint.

In the illustrated embodiment, the fingerprint sensor 300 may bedisposed directly beneath button cap 110. In this way, fingerprintsensor 300 is positioned the smallest distance possible from the surfacea user may engage with the user's finger. One may appreciate that theshorter the distance between fingerprint sensor 300 and the user'sfinger (not shown), the more tightly capacitively coupled a user'sfinger may be with the fingerprint sensor 300, which in turn may providefor more accurate fingerprint image information.

In certain embodiments, button cap 110 may act as a lens to focus,enhance, or direct input to fingerprint sensor 300. For example, thefingerprint recognition sensor circuit can take advantage of one or moreelectrical characteristics of the button cap 110, such as an anisotropyof the material (such as an aluminum oxide, sapphire, or anotheranisotropic material), to allow the fingerprint sensor circuit to bettersense the epidermis of the user's finger (or optionally, a subdermalportion of the user's finger). This has the effect that the fingerprintsensor 300 circuit would exhibit relatively superior capacitive couplingto the user's finger by virtue of the anisotropy of the button material,with the effect that the fingerprint recognition sensor circuit wouldobtain a relatively superior set of fingerprint image information.Similarly, where applicable, the fingerprint sensor 300 can make use ofother electromagnetic properties of the button cap 110 material toexhibit relatively superior capacitive coupling to the user's finger byvirtue of those other electromagnetic properties of the button material.

In certain embodiments, the transparency of circular button cap 110 maybe limited to a particular band of light. For example, circular buttoncap 110 may permit infrared light to pass through, while reflectingvisible light. In such an embodiment, square sensor 300 may be aninfrared proximity sensor. In certain other embodiments, an ink orpigment layer may be disposed upon the button cap, to give the buttoncap the appearance of having a particular color. The material for theink layer may be chosen, as with the button cap itself, for itselectromagnetic, dielectric, or optical properties. The ink layer mayalso serve to mask or otherwise obscure from view the fingerprint sensor300 as well as other components beneath the button cap 300.

In certain embodiments, the ink layer may be disposed upon the buttoncap in a manner that includes decorative features 115. The decorativefeature 115 may serve as a visual cue to the user of the function of thebutton. In certain embodiments, the decorative feature 115 may include aword, a recognizable symbol, or an image. The decorative features may beapplied in a separate step prior to application of the ink layer or, inother embodiments, the decorative features may be applied in the samestep. The decorative features 115 may be may be of a different color inkthan the ink layer or the decorative features 115 may be formed byselective application of ink within the ink layer itself.

In other embodiments, square sensor 300 may be an imaging sensor. Insuch an embodiment, button cap 110 may be shaped so as to function as alens to focus or distribute light over the area of square sensor 300. Inother embodiments, button cap 110 may be shaped as a non-destructivefilter, having as little effect on light passing through as possible.Accordingly, the material selected for circular button cap 110 may bechosen specifically for its dichroic properties. For example, in oneembodiment the material for button cap 110 may be selected forparticular anisotropic properties with respect to a particularelectrical field, or with respect to particular wavelengths of light.For example, the button cap 110 may be a polarizing light filter.Suitable materials for circular button cap 110 may include plastic,glass, sapphire glass, and other similar materials. In such anembodiment, image artifacts resulting from obstruction by decorativefeatures 115 of the button cap 110 may be accounted for by theelectronic device.

In further embodiments, circular button cap 110 may be semi-flexible.For example, square sensor 300 may be a variable force input sensorwhich measures force a user applies to the circular button cap 110. Incertain other embodiments, circular button cap 110 may be rigid in orderto prevent varied force across square sensor 300.

One may appreciate that square sensor 300 may impact the quality, type,or properties of the material selected for button cap 110.

FIG. 3 is a top plan view of a button assembly for receiving anenvironmental seal. The button assembly may include a circular trim ring360, a rectangular base portion 320, and fiducial markers 330 a, 330 b,and 330 c. Also shown is the perimeter of square sensor 300. In oneembodiment, the trim ring 360 can be used to shield electromagneticeffects (i.e. provide grounding), and thereby providing capacitanceisolation or other electromagnetic isolation. The trim ring 360 is shownin the figure as having a cylindrical edge which holds the button cap110 (see FIG. 2), and a base portion 320 which can be aligned ororiented within the device 100 (see FIG. 2) when the assembly isconstructed. The positioning and number of fiducial markers 330 a, 330b, and 330 c may vary. Circular trim ring 360 may also include along itsinterior sidewall perimeter a partial perimeter shelf 340 which, asshown, is divided into four separate portions. The partial perimetershelf 340 as illustrated extends into the interior of circular trim ring360 a distance bounded by the diameter of a smaller concentric circle.One may appreciate however, that different shapes for both the trim ring360 and partial perimeter shelf 340 may be used. For example, partialperimeter shelf 340 of may extend a greater distance from the interiorperimeter of circular trim ring 360 to meet with the edges of a squaresensor 300 inscribed within the interior perimeter of circular trim ring360. In other words, the depth and shape of partial perimeter shelf 340may differ from embodiment to embodiment. In further embodiments, trimring 360 may be an elliptical shape. Correspondingly, the partialperimeter shelf 340 portions may have a different shape along the majoraxis of the elliptical trim ring 360 than the shape of the partialperimeter shelf 340 portions along the minor axis. Further, one mayunderstand that the partial perimeter shelf may be separated into moreor fewer portions than the four as illustrated.

Between individual portions of the partial perimeter shelf 340 aresidewall openings 350. These openings may be of any suitable shape orsize so as to allow the corners of square sensor 300 reach the sidewallof the trim ring 360. In this way, square sensor 300 occupies themaximum area possible while remaining bounded by the circumference ofthe circular button cap 110 (see FIG. 2).

FIG. 4A is an isometric side view of an exploded button assembly 400showing a button cap 410 and a first portion of the environmental seal470 a-d as shown in FIG. 3. FIG. 4A shows the button cap 410 and a firstportion of an environmental seal composed of adhesive film components470 a-d. Also visible is one of four portions of the partial perimetershelf 440, labeled as 440 a, placed approximately halfway between a baseportion 420 and the top of the trim ring 460. Also visible areadditional portions of the partial perimeter shelf 440 b and 440 d.Between each portion of the partial perimeter shelf is a sidewallopening 450. Also visible are fiducial markers 430 a, 430 b. Fiducialmarkers 430 a, 430 b, and 430 c (not visible) may be used duringassembly as a point of reference or measure for automated assemblyequipment to accurately and repeatedly locate portions of the buttonassembly 400.

Each of the four portions of the partial perimeter shelf 440 correspondsto an adhesive film component 470 a-d. For example, the partialperimeter shelf portion 440 a corresponds to the film component 470 a,the shelf portion 440 b to the film portion 470 b and so on. In a firstprocess, the film portions may adhere to the corresponding shelfportions and to the underside of the button cap 410. Thereafter, thebutton cap 410 may be set within the trim ring 460 so that the buttoncap 410 rests along the partial perimeter shelf 440 and adheres to theperimeter shelf with the film components 470 a-d. FIG. 4B illustratesthe button cap 410 after it is placed along the partial perimeter shelf440. In some embodiments, the button cap 410 may have a slightly smallerdiameter than the interior diameter of the trim ring 460. In this case,as illustrated in FIG. 4B, a gap 480 may be present. The gap 480 may beused in a later process as a volume to accept an injected adhesive. Onemay appreciate that the gap 480 may be either larger or smaller than asshown in FIG. 4B.

FIG. 5 is a fragmentary view of a schematic cross section of thelaminated layers of a button and sensor assembly taken along line 5-5 ofFIG. 3. In this cross section, one of two diametrically opposing ends ofthe trim ring 560 is shown. Also shown is the circular button cap 510.Of note is that line 5-5 does not intersect any portion of the partialperimeter shelf. Instead, FIG. 5 shows a cross section through sidewallopening 350 (not shown in FIG. 5, see FIG. 3).

The button assembly 500 includes a slight recessed shape formed at leastin part by a portion of the button cap 510 to guide the user's fingeronto the button. The button cap 510 is disposed within the trim ring560. Also shown in FIG. 5 is gap 580, which illustrates a separationbetween the circular button cap 510 and the interior perimeter of thetrim portion 510.

In one embodiment, an ink assembly including multiple layers of ink 520,is disposed below the button cap 510. In one embodiment, the inkassembly can be printed on the button cap 510, vapor deposited thereon,or applied by another technique. This has the effect that theotherwise-translucent button cap 510 can be made opaque or partiallyopaque so the internal elements of the fingerprint sensor and buttonassembly are not immediately visible to the user. In this cross section,the button cap 510 may be coupled at its edges to the trim ring 560using a perimeter sealant 570.

In some embodiments, the perimeter sealant 570 may be injected fromeither the top or the bottom portion of the button assembly 500 into thegap 580. The perimeter sealant 570 may, in certain embodiments, beinjected as a liquid adhesive that may cure when subjected toappropriate curing conditions, such as heat or ultraviolet light. Theperimeter sealant 570 may adhere to the edges of button cap 510 and mayalso adhere to the interior sidewall perimeter of trim portion 560,creating a seal when cured. In further embodiments relating to thiscross section, the perimeter sealant 570 may also adhere a corner 530 aof the fingerprint sensor 530 (described in further detail below) to theinterior sidewall of the trim portion 560.

In certain embodiments, the perimeter sealant 570 may be injected as asingle dot of liquid adhesive or, in other cases, it may be injected asa stream or jet of liquid adhesive. In certain further embodiments, theperimeter sealant 570 may be of sufficiently low viscosity such that itmay expand to fill the gap 580 by capillary action. Although theperimeter sealant 570 is shown with concave meniscuses, it is understoodthat varied material choices for the perimeter sealant 570 may causedifferent meniscus shapes to form along the trim portion 560 and thebutton cap 510. It is further understood that various material choicesfor the button cap 510 and the trim portion 560 may have differentadhesion characteristics with the perimeter sealant 570. One mayappreciate, however, that the materials of the perimeter sealant 570,the trim portion 560, and the button cap 510 must be chosen such thatthe perimeter sealant 570 may effectively bond with both the trimportion 610 and the button cap 660.

The fingerprint sensor and button stack disposed below the button cap510 may include a liquid lamination layer 522. In some embodiments, theliquid lamination layer 522 is disposed below the ink layer 520. Theliquid lamination layer 522 may serve to couple or otherwise adhere thefingerprint sensor 530 to the button cap 510. The fingerprint sensor 530may be coupled to a flexible element 524. The flexible element 524 maybe further coupled or otherwise adhere to a stiffener element 526. Thestiffener element 526 may be disposed above and coupled or otherwiseadhere to a high-strength bonding tape, such as VHB (very high bond)tape 528, which may be in turn disposed above and coupled or otherwiseadhere to a flexible element 532 and to the tactile switch (buttonswitch) 534. The stiffener element 526 may provide rigidity to thebutton stack and may cooperate with the flexible element 524 to moreuniformly distribute any force applied when a user depresses orotherwise engages the button cap 510.

One may appreciate that the assembly as described provides thefingerprint sensor with relatively short distance to the user's finger,and relatively short stacking height, while concurrently allowing theuser to access a push button or other element of the device using thefingerprint recognition sensor.

FIG. 6 is a fragmentary view of a schematic cross section of thelaminated layers of a button and sensor assembly taken along line 6-6 ofFIG. 3. In this cross section, one of two diametrically opposing ends ofthe trim ring 660 is shown. Also shown is the circular button cap 610.Of note is that line 6-6 intersects a portion of the partial perimetershelf 640, but does not intersect a sidewall opening 360 (not shown inFIG. 6, see FIG. 3) such as shown in FIG. 5.

The cross section of partial perimeter shelf 640, as shown in FIG. 6,extends a certain distance into the interior volume of the trim ring660. The button cap 610 is coupled to the top surface of the partialperimeter 640 shelf through the adhesive film 670 b. The adhesive film670 b may be of any suitable material that adheres to both the trim ring660 and to the underside of the button cap 610. In certain embodiments,the adhesive film 670 b may be cured with heat, pressure, or ultravioletlight, or any combination thereof. In further embodiments, the adhesivefilm 670 b may be a liquid adhesive. Also in this cross section, thebutton cap 610 may be coupled at its edges to the trim ring 660 using aperimeter sealant 670 a. In some embodiments, the perimeter sealant 670a may be injected from either the top or the bottom portion of thebutton assembly 600 into the gap 680. In further embodiments, theperimeter sealant 670 a may fill the gap 680 by capillary action from aninjection point at 580, as shown in FIG. 5. The perimeter sealant 670 amay, in certain embodiments, be a liquid adhesive that may cure whensubjected to appropriate curing conditions, such as heat or ultravioletlight. The perimeter sealant 670 a may adhere to the edges of theadhesive film 670 b and may also adhere to the interior sidewallperimeter of the trim portion 660, creating a contiguous environmentalseal when cured. In certain embodiments, the perimeter sealant 670 a maynot necessarily adhere or otherwise chemically bond with the edges ofthe adhesive film 670 b, but may instead extend by capillary action tomeet and interface the edge of the adhesive film 670 b.

In certain embodiments, such as that shown in FIG. 6, the adhesive film670 may not extend along the entire width of the partial perimeter shelf640, but may instead extend from the inner edge of the partial perimeter640 shelf a distance toward the interior perimeter of the trim ring 660that does not extend to the outer edge of the button cap 610. In thisconfiguration, a small volume that is substantially L shaped in crosssection remains, formed by the interior sidewall of the trim ring 660,the top portion of the partial perimeter shelf 640, the edge of theadhesive film 670 b, and the outer perimeter of the button cap 610. Theperimeter sealant 670 a may fill this volume when applied.

In certain embodiments, the perimeter sealant 670 a and the adhesivefilm 670 b may bond to one another in a single curing process to form asingle seal 670. In some embodiments, the seal 670 may have the twoparts cured in separate processes from one another. For example the sealportion 670 a (perimeter sealant as shown) may be cured first, and theseal portion 670 b (adhesive film as shown) may be cured second. Inalternate embodiments, the opposite curing order may be used. In furtherembodiments, both seal portions 670 a, 670 b may be cured in the sameprocess. In certain embodiments, the seal portions 670 a, 670 b may cureunder different conditions. For example, the adhesive file 670 b maycure with pressure and heat applied whereas the perimeter sealant 670 bmay cure under a certain wavelength of ultraviolet light. One mayappreciate that regardless the order or curing type, when the sealportions 670 a, 670 b are both cured, they may function as a singleunitary seal.

As with FIG. 5, the button assembly 600 illustrated in FIG. 6 includes arecessed shape formed at least in part by a portion of the button cap610 to guide the user's finger onto the button. The button cap 610 isdisposed within the trim ring 660, forming a gap 680. The layers of ink620 may be disposed below the button cap 610, above the fingerprintsensor 630. The fingerprint sensor 630 and the button stack disposedbelow the button cap 610 includes the liquid lamination layer 622 which,as in FIG. 5, couples or otherwise adheres the fingerprint sensor 630 tothe button cap 610. The fingerprint sensor 630 is also coupled orotherwise adhered to a flexible element 624 which is further coupled oradhered to a stiffener element 626. The stiffener element is disposedabove and coupled or otherwise adhered to a high-strength bonding tape628, which is in turn disposed above and coupled or otherwise adhered toa flexible element 632 and to a tactile switch (button switch) 634. Thestiffener element 626 may also be coupled or otherwise adhered to thebottom portion of the partial perimeter shelf 640 via the adhesive film636. The stiffener element 626 may provide rigidity to the button stackand may cooperate with the flexible element 624 to more uniformlydistribute any force applied when a user depresses or otherwise engagesthe button cap 610.

Both FIGS. 5 and 6 show cross section views of the button assembly aspartially described in FIGS. 4A and 4B. Each cross section shows acomponent stack which generally includes a button cap atop a fingerprintsensor atop structural components atop a physical button. As shown, thecomponent stack may be multiple layers. At the base of the componentstack, an inverted dome switch, or other tactile switch is may beplaced. In this manner, when the button cap is depressed by the user,the entire component stack may be compressed downward, exceeding amaximum force threshold for dome switch, causing the switch to activate.

FIG. 7 is a top plan view of the button assembly of FIG. 4A showing atop view of a cured environmental seal 770, which is formed from thecombination of both a first seal portion 770 a and a second seal portion770 b of the environmental seal 770. For illustrative purposes, internalcomponents and the button cap are not shown.

FIG. 8 is a representative flowchart of an exemplary method of sealing avolume. First an assembly having an interior volume is selected in step800. As described above, the interior volume may be a button assemblythat has at least a first and second shelf portion extending separatelyinto the interior of the volume from a sidewall. In other embodiments,more than two shelves may be present, as, for example, the embodimentsdisclosed above.

Next, a first adhesive of a first adhesive type may be applied to a topface of the first shelf portion at step 810. In certain embodiments, thefirst adhesive may be, as described above, a heat activated film. In thesame step, a second adhesive strip of the same type as the firstadhesive may be applied to the second shelf.

Next, the button cap may be positioned above the first and second sealsas indicated in step 820. In certain embodiments, the cap is posited toextend and adhere to both the first adhesive and the second adhesive, orin other words, to rest on the shelf portions that extend into theinterior of the volume of the assembly.

Next, a third adhesive of a second adhesive type may be applied toadhere the cap to the at least a first portion of exposed interiorsidewall as indicated in step 830. In this case the second adhesive typemay be a liquid adhesive that is of sufficiently low viscosity so thatit is drawn by capillary action into areas adjacent to the injectionpoint. For example, the third adhesive may be injected immediately abovea portion of exposed interior sidewall or, in other words, injectedadjacent to but not above a shelf portion. In such an embodiment,capillary action may draw the third adhesive to the area proximate thefirst and second shelves. In certain embodiments the third adhesive mayinteract with the first and second adhesives to form a singular bond andsingular seal between the interior sidewall of the assembly and thebutton cap.

Next, the assembly may be placed in conditions appropriate for curing asindicated in step 840. For example, if the first adhesive type is a heatactivated film and the second adhesive type is an ultraviolet curingliquid adhesive, the assembly may be placed in a curing oven that alsoemits ultraviolet light of appropriate wavelength for curing the liquidadhesive. In such an embodiment, the two types of adhesive are curedsubstantially simultaneously. In other embodiments, the adhesives may becured in a multi-step process. For example, the assembly may be placedin a curing oven first and thereafter bathed in curing ultravioletlight. In further embodiments, the first adhesive may be cured beforethe second adhesive is applied. In still further embodiments, internalcomponents may be placed beneath the button cap before either adhesiveis applied or cured. For example, a sensor stack as described above maybe adhered directly to a button cap. The sensor stack and button cap maythen be inserted into the interior volume of the assembly, after whichthe two adhesive types may be applied and the assembly may be cured.

One may appreciate that although many embodiments are disclosed above,that the operations presented in FIG. 8 are meant as exemplary andaccordingly are not exhaustive. One may further appreciate thatalternate step order or additional or fewer steps may be used toaccomplish the same method.

FIG. 9 is another representative flowchart of an exemplary method ofsealing a volume. Similar to FIG. 8, in the first step 900 an assemblyis selected having an interior volume that may include a button assemblywhich has at least a first and second shelf portion extending separatelyinto the interior of the volume from an interior perimeter sidewall. Inother embodiments, more than two shelves may be present.

Next, the button cap may be positioned resting above the first andsecond shelf portion in step 910.

Next, a temporary adhesive dam may be applied to overlap the first andsecond shelf portions and the button cap as indicated in step 920. Inthis way the temporary adhesive dam creates a temporary interior volumebetween the interior perimeter sidewall of the assembly and the edges ofthe button cap.

Next, a seal portion may be applied by injecting an adhesive to adherethe cap to the at least a first portion of exposed interior sidewall asprovided in step 930. In this case the adhesive type may be a liquidadhesive that is of sufficiently low viscosity so that it is drawn bycapillary action into areas adjacent to the injection point. Forexample, the adhesive may be injected immediately above a portion ofexposed interior sidewall, or may be injected above a shelf portion. Insuch an embodiment, capillary action may draw the third adhesive to thearea proximate the first and second shelves, and to areas proximate theexposed shelf portions. In certain embodiments the adhesive fill theentire volume created between the temporary adhesive dam, the undersideof the button cap, the edge of the button cap, and the interiorperimeter sidewall of the assembly.

Next, the assembly may be placed in conditions appropriate for curing asindicated in step 940. For example, if the adhesive type is anultraviolet curing liquid adhesive, the assembly may be bathed inultraviolet light of appropriate wavelength for curing. Finally, thetemporary damn may be removed after curing is complete as provided instep 950.

The embodiments described herein related to an environmental seal thateffectively prevents ingress of foreign matter while maximizingavailable space within a sealed interior volume of a component assemblyfor use within a portable electronic device. In certain embodiments, aninterior volume of a component assembly may house at least a button anda fingerprint sensor. When a user engages an upper surface of thecomponent assembly, the dual purpose of activating the button andreading the user's fingerprint is accomplished.

Although the invention is described above in terms of various exemplaryembodiments and implementations, it should be understood that thevarious features, aspects and functionality described in one or more ofthe individual embodiments are not limited in their applicability to theparticular embodiment with which they are described, but instead can beapplied, alone or in various combinations, to one or more of the otherembodiments of the invention, whether or not such embodiments aredescribed and whether or not such features are presented as being a partof a described embodiment. Thus, the breadth and scope of the presentinvention should not be limited by any of the above-described exemplaryembodiments but is instead defined by the claims herein presented.

1-20. (canceled)
 21. An electronic device incorporating a sealedelectrical sensor assembly, the electronic device comprising: a housingdefining an aperture; the sealed electrical sensor assembly disposedwithin the aperture and comprising: an electrical sensor having arectangular shape; a circular trim ring circumscribing the electricalsensor, the circular trim ring comprising a shelf that extends to meetan edge of the electrical sensor; and a circular cap disposed over theelectrical sensor and the shelf, the cap sealed to at least one of thecircular trim ring or the shelf.
 22. The electronic device of claim 21,wherein the sealed electrical sensor assembly further comprises: a firstsealant disposed between the circular cap and the shelf; and a secondsealant disposed between the circular cap and an internal trim ring ofthe circular trim ring.
 23. The electronic device of claim 21, whereinthe electrical sensor is a capacitive fingerprint sensor.
 24. Theelectronic device of claim 21, wherein the circular trim ring iselectrically conductive.
 25. The electronic device of claim 21, whereinthe circular cap is formed from a dielectric material.
 26. Theelectronic device of claim 21, wherein the shelf is a first shelf andthe edge is a first edge; and the sealed electrical sensor assemblyfurther comprises: a second shelf extending to meet a second edge of theelectrical sensor; a third shelf extending to meet a third edge of theelectrical sensor; a fourth shelf extending to meet a fourth edge of theelectrical sensor;
 27. A sealed electrical sensor assembly for anelectronic device, the assembly comprising: a trim ring defining aninterior volume; a shelf portion extending from an inner sidewall of thetrim ring into the interior volume; a cap sealed to the shelf and to thetrim ring with at least one adhesive; and a capacitive sensor disposedbelow the cap and abutting the shelf.
 28. The sealed electrical sensorassembly of claim 27, wherein: the first adhesive is a heat activatedfilm; and the second adhesive is a liquid adhesive.
 29. The sealedelectrical sensor assembly of claim 27, wherein the electrical sensor isa finger print sensor.
 30. The sealed electrical sensor assembly ofclaim 27, wherein the electrical sensor has a square shape and the trimring has a circular shape.
 31. The sealed electrical sensor assembly ofclaim 27, wherein: the electrical sensor is a capacitive sensor; and thecap comprises an anisotropic material.
 32. The sealed electrical sensorassembly of claim 31, wherein the cap is formed from sapphire.
 33. Asealed electrical sensor assembly comprising: a trim ring having aninterior sidewall that defines a first interior volume having a roundcross-sectional shape; a set of shelves extending from the interiorsidewall and at least partially defining a second interior volume havinga square cross-sectional shape, the second interior volume within thefirst interior volume; a capacitive sensor positioned adjacent the shelfand within the second interior volume; and a cap positioned at leastpartially within the first interior volume and over the capacitivesensor.
 34. The sealed electrical sensor assembly of claim 33, wherein:the cap is sealed to at least a portion of the set of shelves with afirst adhesive; and the cap is sealed to at least a portion of theinterior trim ring with a second adhesive.
 35. The sealed electricalsensor assembly of claim 33, wherein the trim ring is formed from metal.36. The sealed electrical sensor assembly of claim 33, wherein the trimring is electrically grounded.
 37. The sealed electrical sensor assemblyof claim 33, the first cross-sectional shape is a circle.
 38. The sealedelectrical sensor assembly of claim 33, wherein the electrical sensor isa capacitive fingerprint sensor.
 39. The sealed electrical sensorassembly of claim 33, wherein the electrical sensor is an infraredsensor.
 40. The sealed electrical sensor assembly of claim 33, furthercomprising an ink layer disposed on a bottom surface of the cap.